HU181107B - Plate floor heat exchanger - Google Patents

Abstract

A plate floor heat exchanger has a plurality of conductive mutually parallel plates spaced apart by narrow gaps defined by spacer bands which can have a streamlined shape and each of which are traversed by a plurality of tubes extending perpendicular to the plates. The spaces between longitudinal edges of these bands define flow channels for a fluid in a heat exchange relationship with the fluid traversing the tubes.

Description

FIELD OF THE INVENTION The present invention relates to a plate-to-plate heat exchanger having at least two plates of any section and spacing spaced apart in at least one region of their surface, at least one closed profile channel of arbitrary cross-section through the plates and a spacer between the plates.

The plate-to-plate heat exchanger of the present invention is particularly useful in areas where the heat transfer coefficient of the fluid flowing in the channel is much higher than that of the fluid flowing between the sheet fins. This is usually the case for air coolers, air cooled condensers, air heaters, radiators and air conditioners.

Various devices are known for similar applications, in which one of the fluids involved in the heat exchange flows through a closed profile channel of arbitrary mesh cross-section and the other medium flows between the plate fins. The spacing between the plate fins is provided by spacers, which may be separate spacers (spacer rings) or flanges formed on the plate fins.

A feature of the above solutions is that during operation, the spacers or ducts represent a significant fluid resistance through the fluid flowing between the plate fins. In the "edge gutter" of the channels or spacers, that is, along a side opposite to the flow direction of the fluid flowing between the sheet fins, a so-called "dead space" is formed within the space narrowing between the outer wall of the channels and the flow stream. not by flow but practically by driving 5.

As a result, the dead space boundary surfaces are practically not involved in heat transfer, and furthermore, the vortices formed in the dead space significantly increase the fluid resistance, so that the flow of fluid in the space between the fins is much more efficient. If the spacer element is formed by fluting the sheet metal, the heat transfer is also impaired by the thin compression of the sheet material due to the fluting.

Various solutions to avoid or reduce the above disadvantages are also known. The essence of these is that the ducts are formed from oval or elliptical tubes which are elongated in the direction of flow of the fluid flowing between the fins 20 in order to reduce fluid resistance and dead space. Such a solution is also described in German Patent No. 2,123,723, as well as in other literature (see Transaction of the ASME, 25 Serre "B", May 1966).

Oval tubing and the like are characterized by the fact that dead spaces are reduced but not eliminated, so that the flow properties of the plate-like heat exchangers thus formed can be improved but can be further improved.

When using oval or elliptical tubes, it is difficult to ensure that the metallic connection providing good heat conduction between the channel and the plate fins is maintained throughout the operation. In fact, when such a cross-sectional tube is placed under operating or test pressure, the cross-section of the tube will tend to take up the cross-section as a result of the pressure. Repeating this process may loosen the metallic connection between the tube and the sheet metal, which will reduce heat transfer.

In addition to the drawbacks described, the oval or elliptical tube is • less robust and more complicated to manufacture and therefore more expensive.

It is an object of the present invention to provide a plate-ribbed heat exchanger which is free of the above disadvantages, that is to say, it has no dead space that impairs the thermal properties and does not develop vortex separations that increase the fluid resistance.

The plate heat exchanger of the present invention has a lower fluid resistance than at present, but has a higher heat transfer coefficient and these advantageous properties are achieved in conjunction with the simplification of the manufacture.

The present invention is based on the discovery that the formation of dead spaces behind the channels is most easily and effectively prevented by filling the space between the ribs with solid material in place of the dead spaces behind the channels, providing a flow channel for the fluid flowing between the ribs.

In this way, the fluid properties of the heat exchanger, and thus its fluid resistance, can be independent of the shape of the cross-section of the duct.

The object of the present invention is to modify known plate-ribbed heat exchangers so as to exclude areas of vortex separation and dead spaces in known heat exchangers, or at least some of them from the flow space.

According to the invention, the above object is solved by providing at least two of the plate-to-plate heat exchangers according to the invention. at least one region of their surface having spaced spaced sections of arbitrary section and design, at least one closed profile passageway of any cross-section through the webs, and a spacer member spaced between the webs.

In a preferred embodiment of the plate-ribbed heat exchanger according to the invention, at least two passageways pass through at least one spacer belt, the channels being preferably circular tubes.

An advantage of the above embodiment is that installation of a multi-channel spacer belt and manufacture and maintenance of the heat exchanger are simpler.

In a further preferred embodiment of the plate-ribbed heat exchanger according to the invention, the width of the spacer belt ¹ varies along its longitudinal axis, preferably in the vicinity of the channel.

An advantage of the above embodiment is that the flow and thermodynamic characteristics of the heat exchanger can be advantageously varied and matched with such a spacer belt design.

In a further preferred embodiment of the plate-ribbed heat exchanger according to the invention, the width of the spacer belt varies continuously between two maximum width positions along its longitudinal axis, and the first derivative of the function describing the change has at most one negative and positive signed area between two successive maximum width positions.

The advantage of the above embodiment is that the width of the spacer band can be reduced in the passage between the channels and thus the heat transfer surface of the sheet ribs can be increased, while the flow properties of the heat exchanger can be advantageously created due to the continuity of width changing. THE

In a further preferred embodiment of the sheet rib heat exchanger according to the invention, the sidewall (s) or at least one section thereof of the consecutive spacer ribs (s) form a streamline flow space along the sheet ribs.

An advantage of the above embodiment is that the fluid flowing between the sheet fins can be flowed with the least amount of energy loss in the flow stream space formed as described above.

In a further preferred embodiment of the plate-ribbed heat exchanger according to the invention, at least a portion of the sidewall surface area of the at least one spacer has a serrated, corrugated, knurled, or etched or otherwise increased surface.

The advantage of the above embodiment is that the turbulence generators formed on the sidewall of the spacer belts do not substantially increase the fluid resistance, but they improve the heat transfer and increase the heat transfer surface.

In another preferred embodiment of the plate-ribbed heat exchanger of the invention, the axis of the at least one spacer belt is a two- or three-dimensional spatial curve.

An advantage of the above embodiment is that the flow direction of the fluid flowing between the sheet fins within the heat exchanger can be changed, or the residence time of this fluid can be increased without reducing the speed.

In a further advantageous embodiment of the plate-ribbed heat exchanger according to the invention, the surface of the plate-ribs is provided with turbulence-forming, preferably small, ribs, preferably terminating near the side-facing surfaces of the spacer strips.

The advantage of the above embodiment is that the turbulence generators formed on the surface of the sheet fins further improve the heat transfer and the spacer strips which are considerably thicker than the sheet fins provide good heat supply to the fins located further away from the closed channels. A further advantage is that the ends of the small ribs touch the sidewall of the spacer strips and thus the heat transfer also takes place on these opposing surfaces.

In a further preferred embodiment of the sheet rib heat exchanger according to the invention, the channels, sheet ribs and spacers are in metallic contact and have a better thermal conductivity than that of the fluid flowing between the sheet ribs.

An advantage of the above embodiment is that the heat transfer can be further improved.

In a further preferred embodiment of the plate-ribbed heat exchanger according to the invention, the spacer strip is formed of strip sections, the flow gap between the strip sections preferably not exceeding the maximum width of the spacer strip.

An advantage of the above embodiment is that, where construction or manufacturing reasons justify it, the spacer element in its essence and function can also be formed from strip sections. In fact, such an arrangement can provide the flow of the medium in the strip, while of course it is generally advantageous to min-10 the gap between the strip sections.

_Λ plate fin type heat exchanger according to the invention further advantageous embodiment of the lemezbordával távtartószalag forms a common structural unit, and * it is preferably formed in the material. 15

An advantage of the above embodiment is that the spacer belt forms an organic unit, preferably is formed in one step with the plate rib, and is preferably made of its material. This simplifies both manufacturing and assembly. 20

Embodiments of the invention will now be described, by way of example only, with reference to the drawings, in which:

Figure 1 is a plan view of an embodiment of a plate-to-plate heat exchanger according to the invention; the 25th

Figure 2 is a sectional view A-A of the plate-to-plate heat exchanger of Figure 1; the

3-5. Figs. 4A are plan views of a portion of possible embodiments of spacers; the

5-8. Figures 4A and 5B illustrate structural arrangements of further embodiments of the plate ribbed heat exchanger 30 of the present invention.

1-2. The plate-to-plate heat exchanger illustrated in FIG. 6B is made up of plate fins 1, spacer strips 2 and channels 35. The spacer strips 2 are threaded between the ribs 1 on the channels 3 so that a fluid-like flow space is provided for the fluid flowing in the space between the spacer strips 2. The other medium involved in the heat exchange flows through the channels 3 40.

Fig. 3 shows a spacer strip 2 having a tooth 2a on its sidewall, wherein the turbulence generated by the tooth 2a improves the heat transfer without significantly increasing the fluid resistance. 45

Fig. 4 shows a spacer strip 2 of variable width along its longitudinal axis, whereby the reduction in width increases the size of the free heat transfer surface of the sheet fins 1.

In the embodiment of the plate fin heat exchanger 5 according to Fig. 50, the plate fins 1 are provided with small turbulence-generating fins 5 which improve the heat transfer. The direction of flow 4 in the heat exchanger is at an angle other than right angles to the entry plane because it is parallel to the longitudinal axis 55 of the spacer strips.

6, the spacer strips 2 have a flat curve, so that the flow direction of the flow medium 4 changes within the heat exchanger, thus extending the heat exchanger ₆₀ and increasing its residence time.

In the embodiment of the plate fin heat exchanger according to the invention, the fins 5 formed on the surface of the plate fins 1 practically extend to the lateral surface of the spacer strips 55. As shown in the figure, the cross section 7 passes through a plurality of heat fluxes of a plurality of small ribs 5. This cross-section 7 is considerably larger when using the spacer strips than when using spacer rings, and thus the thermal resistance is greatly reduced.

8, the spacer strips 2 are formed of strip portions having an air gap between them but together form a strip-shaped flow space for conducting the fluid, where the flow direction 4 is also determined.

The advantage of the plate-ribbed heat exchanger of the present invention is that it eliminates dead space and vortex separations that are extremely damaging to the heat exchanger, both thermologically and flow-wise. The fluid resistance of the heat exchanger can be independent of the shape of the cross-sections of the ducts, so it can be thermo, manufacturing, etc. is optimum from the point of view because the optimum of flow can be approximated by the design of spacers.

A further advantage is that the thermal load of the ducts becomes uniform around their circumference. The resistance of the heat exchanger is significantly reduced, so that the energy required to flow the fluid between the ribs is reduced, thus increasing the specific ventilation power (the ratio of energy derived and maintaining the fluid flow).

A further advantage of the heat exchanger according to the invention is the simplicity of manufacture, maintenance and stability of its properties over time.

Claims (3)

Patent claims: The first plate fin heat exchanger having at least two surfaces spaced apart at least a region of an arbitrary cross-section and establish ASU plate rib, azokónatKatóló least ^- a zartprofilú channel tree ^- is, although the spacing member is characterized in the plate fin, that the spacing element is távtartószalag (2 ) having a variable width and preferably having the largest width around the closed channel (3). The plate-to-plate heat exchanger according to claim 1, characterized in that at least two closed channels (3) are at least partially passed through at least one spacer belt (2), wherein g closed channels (3) are preferably circular tubes. 3. ~~ Kz ~ 1-2. A plate-to-plate heat exchanger according to any one of claims 1 to 4, characterized in that the width of the spacer belt (2) is continuously variable between two positions of equal width and the first derivative of the function expressing the change has at most one negative and positive sign region. 4. A plate-to-plate heat exchanger according to any one of claims 1 to 3, characterized in that the side-plates of the successive spacers (2) or At least one section of 181101 is arranged to form a streamline flow space. '5th 1-4. A plate-to-plate heat exchanger according to any one of claims 1 to 3, characterized in that at least part of the sidewall surface of the at least one spacer strip (2) has a tooth (2a) or is corrugated, knurled or enlarged. 6. A plate-to-plate heat exchanger according to any one of claims 1 to 3, characterized in that the axis of the at least one spacer belt (2) is a planar or spatial curve. 7. A plate-to-plate heat exchanger according to any one of claims 1 to 3, characterized in that the sheet-plates (1) are provided with small ribs (5) which preferably end at or close to the side-facing surfaces of the spacers (2). 8. A plate-to-plate heat exchanger according to any one of claims 1 to 3, characterized in that the sealed channels (3), the plate fins (1) and the spacer strips (2) are in metallic contact or have a material with better thermal conductivity than the fluid flowing between the plates. The plate-to-plate heat exchanger of any one of claims 1-8, wherein Because the spacer strip (2) is formed of sections, the flow gap between the sections is preferably smaller than the largest width of the spacer strip (2). 10. A process according to any one of claims 1 to 4 An embodiment of a plate-like heat exchanger 10, characterized in that the spacer belt (2) is formed as a unit, preferably of its material, which is common to the plate plate (1). 11. A plate-to-plate heat exchanger according to any one of claims 1 to 3, characterized in that the largest width portions of the spacer belts (2) are disposed opposite to the smallest width portions of the adjacent spacer belts (2) and the largest width portions located opposite the smallest width portions. 3 drawings